DE69011482T2 - Level measuring device. - Google Patents

Description

The present invention relates to a level measuring device and, in particular, to a level measuring device for determining the level of a liquid or a powdery material.

A conventional level measuring device comprises level detecting resistors, a temperature compensating resistor having the same temperature characteristics as those of the level detecting resistors, and two resistance measuring circuits for measuring the respective resistance values of the level detecting resistors and the temperature compensating resistor. In this case, the temperature compensating resistor is coated with an insulating material, allowing it to be electrically insulated from the level detecting resistors.

In a measuring device where the level detecting resistors are short-circuited, e.g. by an electrolyte contained in a container, the resistance value output from the resistance measuring circuit connected to the level detecting resistors changes linearly as the liquid level changes in a range from the lower end portion of the level detecting resistor to the upper end portion thereof.

Thus, the liquid level is determined by the resistance values mentioned above.

The inclination of the straight line showing the relationship between the resistance value and the liquid level depends on the temperature due to the temperature characteristic of the level detection resistor. Namely, the resistance value changes not only by the liquid level but also by the temperature.

In view of the above, the conventional level measuring device further comprises a calculation circuit (or a processor) for reading a resistance value obtained from the resistance measuring circuit connected to the temperature compensation resistor is output to perform a temperature compensation operation based on the resistance value thus read.

However, since the above-mentioned conventional level measuring device requires two resistance measuring circuits and a calculation circuit (or processor), there was a problem of complicated construction and increased cost.

Accordingly, an object of the present invention is to provide a simply constructed and inexpensive level measuring device.

According to the present invention, a level measuring device is provided, comprising:

a level detection resistor;

a temperature compensation resistor with the same temperature characteristic as that of the level detection resistor; and

an amplifier circuit in which one of said level detecting resistor and said temperature compensating resistor is connected as an input resistor to a negative input terminal of an operational amplifier, and the other of said resistors is connected between said negative input terminal and an output terminal as a negative feedback resistor of said operational amplifier, whereby the gain of said amplifier is determined by the ratio of said resistors.

Note that when the level of a liquid or powdered material changes, the resistance value of the level detection resistor and, consequently, the gain also changes.

If a reference signal is fed to the amplifier circuit for this reason, the output signal assumes values that correspond to the fill level changes. This allows the fill level to be determined.

When any temperature change occurs, the resistance value of the level detection resistor changes, but the resistance value of the temperature compensation resistor changes in a similar way. As described above, since the gain is determined by the ratio between the resistance values of the two resistors, such changes in the ratio do not occur when the resistance values of the two resistors undergo a similar change depending on the temperature. Thus, the temperature has no effect on the gain.

This means that the filling level can be determined without being influenced by temperature changes using a simple and cost-effective design.

The present invention will now be described in detail by way of example and with reference to the accompanying drawings, in which:

Fig.1 is an explanatory view of an embodiment of the present invention of a circuit configuration of a level measuring device;

Fig.2 is a characteristic diagram of the level measuring device shown in Fig.1;

Fig.3 is an explanatory view of a circuit configuration of another embodiment of a level measuring device according to the present invention;

Fig.4 is a characteristic diagram of the level measuring device shown in Fig.3;

Fig.5 is an explanatory view of a circuit configuration of another embodiment of a level measuring device according to the invention.

Referring to the drawings, Fig. 1 shows a fill level measuring device 1 in an embodiment according to the invention.

In the level measuring device 1, the measuring device includes level detecting resistors 3 and a temperature compensating resistor 4 formed on the surface of an insulating substrate 2, in which a portion other than the area 5 with the level detecting resistors 3 is covered with an insulating waterproof film 6.

The amplifier unit consists of an inverting amplifier with a level detection resistor 3 as an input resistor to the negative input terminal of an operational amplifier 7 and the temperature compensation resistor 4 as a negative feedback resistor, wherein a reference signal Ei is fed to the input resistor.

The resistance value RS of the level detection resistor 3 is expressed by the following equation:

RS = (1 - αt) (Lf - L) RSo / (Lf - Le) ... (1)

where RSo is the resistance value at short-circuited lower end portions of the level detecting resistors 3, and at a predetermined temperature, α is the temperature coefficient and t is the temperature difference between a temperature at the time of measurement and the predetermined temperature.

However, the resistance value RC of the temperature compensation resistor 4 is expressed by the following equation:

RC = (1 - αt) RCo ... (2)

where RCo is a resistance value at a predetermined temperature. The temperature coefficient α and the temperature difference t are the same as those in the above equation (1) because the level detection resistors 3 and the temperature compensation resistor 4 are made of materials having the same temperature coefficient and are arranged at close positions to the same substrate 2.

Since the gain of the amplifier unit is expressed as -RC/RS, the output voltage Eo is expressed by the following equation:

Eo = - Ei (Lf - Le) / (Lf - L ) ... (3)

where Ei is the amplitude of the alternating signal supplied to the level measuring device to measure the liquid level, Eo is the amplitude of the output signal of the measuring device, Lf corresponds to the full resistance, Le is related to the empty resistance and L is related to the continuously measured resistance of the level detection resistors.

Thus, the output voltage Eo is only changed by the liquid level L, without being influenced by temperature changes.

Fig.2 is a characteristic diagram showing the relationship between the output voltage Eo and the liquid level L. Since this relationship is shown as an inversely proportional curve so that the resolution is higher as the liquid level approaches the upper end Lf of the level detecting resistor 3, the level measuring device of this construction is suitable for use when the liquid level is maintained at a constant value near the upper end Lf.

For example, the level detection resistor 3 may be an epoxy-molded carbon resistor having a width of 5 mm, a length of 300 mm, and a resistance value of 75 KΩ. The temperature compensation resistor 4 may be an epoxy-molded carbon resistor having a width of 2.5 mm, a length of 300 mm, and a resistance value of 150 KΩ. In addition, the conductor electrode and wiring may be an epoxy-deposited Ag (silver) conductor pattern.

Fig.3 shows a level measuring device 11 in a further embodiment according to the invention.

This level measuring device according to the invention differs from the level measuring device 1 of the first embodiment mentioned in that the level detection resistors 3 serve as negative feedback resistors and the temperature compensation resistor 4 serves as input resistors. In this case, the following relationship exists:

Eo = - Ei (Lf - L) / (Lf - Le) ... (4)

The characteristic shown in Fig.4 is produced. Namely, the output voltage Eo and the liquid level L are in linear relationship with each other. Accordingly, the level measuring device of the present construction is suitable for use when it is required that the resolution be kept constant in a range from the lower end Le to the upper end Lf of the level detecting resistor 3.

Fig.5 shows a level measuring device 21 in a further embodiment according to the invention.

In this level measuring device 21, two temperature compensation resistors 4a and 4b are formed, in which the level detecting resistors 3 and the temperature compensation resistor 4a serve as a negative feedback resistor and the temperature compensation resistor 4b serves as an input resistor. In this level measuring device 21, the range of change of the output voltage Eo can be easily adjusted.

In the explanation of the embodiments described above, the amplifier is composed of an inverting amplifier. However, the present invention can also be applied in a similar manner to the above to those cases where the amplifier unit is composed of a non-inverting amplifier.

It is obvious from the above description that according to the The level measuring device according to the invention can determine the level without being influenced by temperature changes and the level measuring device can be constructed simply and inexpensively.

Claims (1)

1. Level measuring device (1) comprising: a level detection resistor (3); a temperature compensation resistor (4) with the same temperature characteristic as that of said level detection resistor; and an amplifier circuit in which one of said level detection resistor (3) and said temperature compensation resistor (4) is connected as an input resistor to a negative input terminal of an operational amplifier (7), and the other of said resistors (3, 4) is connected between said negative input terminal and an output terminal as a negative feedback resistor of said operational amplifier, whereby the gain of said amplifier (7) is determined by the ratio of said resistors (3, 4). 2. A level measuring device according to claim 1, wherein the level detecting resistor (3) and the temperature compensating resistor (4) are formed on the surface of an insulating substrate (2), and wherein a region, excluding a portion with said level detecting resistor (3), including the temperature compensating resistor (4) is covered with an insulating film (6). 7. Level measuring device (i) comprising: a level detection resistor (3); first and second temperature compensation resistors (4a, 4b) having the same temperature characteristics as those of said level detection resistor: and an amplifier circuit, wherein a series circuit consisting of said level detection resistor (3) and said first temperature compensation resistor (4a) represents a negative feedback resistor of an operational amplifier (7), and wherein said second temperature compensation resistor (4b) represents an input resistor connected to the negative input terminal of said operational amplifier (7), whereby the gain of said amplifier (7) is a function of the ratio of the resistance values of said resistors. 4. A level measuring device according to claim 3, wherein the level detecting resistor (3) and the two temperature compensating resistors (4a, 4b) are formed on the surface of an insulating substrate (2), and wherein a region, excluding a portion with said level detecting resistor (3), including said temperature compensating resistors (4a, 4b) is coated with an insulating film (6).